Abstract
In a tele-abrasive task, it is principally human arm movements that cause variation in the position of the abrasive nozzle, thereby resulting in high operating costs and low productivity. It is difficult to design a system that can minimize the variation that accrues from operators behaving differently, which is difficult to predict. Although skilled operators can reduce this variation, becoming a skillful operator requires a lengthy training period. In this work, a two-stage variation streaming technique was used to extract variation sources in a tele-abrasive system. Furthermore, we propose an integrated human–computer approach to control variation in these systems—an approach that applies an innovative human arm movement pattern incorporated with a Kalman filter into a standard system. A virtual tele-abrasive system was used to validate our approach. Furthermore, compared with conventional systems, the proposed approach will help operators to perform abrasive tasks more comfortably and require a shorter training period.
Highlights
Due to the advancement in telecommunication technology, teleoperation has become a common part of many production systems
The collected data were plotted to determine how the proposed arm movement pattern reformed the variation in the output
We propose a new approach to tele-abrasive systems, consisting of two steps: navigating the arm movement pattern, and using a linear estimation with a Kalman filter
Summary
Due to the advancement in telecommunication technology, teleoperation has become a common part of many production systems. A tele-abrasive system is one of those systems combining a teleoperation system and an abrasive system to clean the surface of a large structure remotely [1,2]. There are several sources that cause system variation, such as visual perception [9], time delay [10], robot calibration [11], and human movement error [12] Among these factors, human movement error in a tele-abrasive task has a unique characteristic and has not been solved. Human movement error in a tele-abrasive task has a unique characteristic and has not been solved This problem occurs when a human operator controls the master controller with a lack of accuracy and precision.
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